Isolation and expression analysis of a human zinc finger gene (ZNF41) located on the short arm of the X chromosome

Unveiling the bovine embryo transcriptome during the maternal-to-embryonic transition

Bovine early embryos are transcriptionally inactive and subsist through the initial developmental stages by the consumption of the maternal supplies provided by the oocyte until its own genome activation. In bovine, the activation of transcription occurs during the 8- to 16-cell stages and is associated with a phase called the maternal-to-embryonic transition (MET) where maternal mRNA are replaced by embryonic ones. Although the importance of the MET is well accepted, since its inhibition blocks embryonic development, very little is known about the transcripts expressed at this crucial step in embryogenesis. In this study, we generated and characterized a cDNA library enriched in embryonic transcripts expressed at the MET in bovine. Suppression subtractive hybridization followed by microarray hybridization was used to isolate more than 300 different transcripts overexpressed in untreated late eight-cell embryos compared with those treated with the transcriptional inhibitor, alpha-amanitin. Validation by quantitative RT-PCR of 15 genes from this library revealed that they had remarkable consistency with the microarray data. The transcripts isolated in this cDNA library have an interesting composition in terms of molecular functions; the majority is involved in gene transcription, RNA processing, or protein biosynthesis, and some are potentially involved in the maintenance of pluripotency observed in embryos. This collection of genes associated with the MET is a novel and potent tool that will be helpful in the understanding of particular events such as the reprogramming of somatic cells by nuclear transfer or for the improvement of embryonic culture conditions.

The epigenetic reprogramming of poorly aggressive melanoma cells by a metastatic microenvironment

A dynamic, complex relationship exists between tumor cells and their microenvironment, which plays a pivotal role in cancer progression, yet remains poorly understood. Particularly perplexing is the finding that aggressive melanoma cells express genes associated with multiple cellular phenotypes, in addition to their ability to form vasculogenic-like networks in three-dimensional matrix - called vasculogenic mimicry, which is illustrative of tumor cells plasticity. This study addressed the unique epigenetic effect of the microenvironment of aggressive melanoma cells on the behavior of poorly aggressive melanoma cells exposed to it. The data show significant changes in the global gene expression of the cells exposed to 3-D matrices preconditioned by aggressive melanoma cells, including the acquisition of a vasculogenic cell phenotype, upregulation of ECM remodeling genes, and increased invasive ability - indicative of an epigenetic, microenvironment-induced reprogramming of poorly aggressive melanoma cells. However, this epigenetic effect was completely abrogated when a highly cross-linked collagen matrix was used, which could not be remodeled by the aggressive melanoma cells. These findings offer an unique perspective of the inductive properties associated with an aggressive melanoma microenvironment that might provide new insights into the epigenetic regulation of tumor cell plasticity and differentiation, as well as mechanisms that could be targeted for novel therapeutic strategies.

The diabetes-prone BB rat carries a frameshift mutation in Ian4, a positional candidate of Iddm1

Diabetes-prone (DP) BB rats spontaneously develop insulin-dependent diabetes resembling human type 1 diabetes. They also exhibit lifelong T-cell lymphopenia. Functional and genetic data support the hypothesis that the gene responsible for the lymphopenia, Lyp, is also a diabetes susceptibility gene, named Iddm1. We constructed a 550-kb P1-derived artificial chromosome contig of the region. Here, we present a corrected genetic map reducing the genetic interval to 0.2 cM and the physical interval to 150-290 kb. A total of 13 genes and six GenomeScan models are assigned to the homologous human DNA segment on HSA7q36.1, 8 of which belong to the family of immune-associated nucleotides (Ian genes). Two of these are orthologous to mouse Ian1 and -4, both excellent candidates for Iddm1. In normal rats, they are expressed in the thymus and T-cell regions of the spleen. In the thymus of lymphopenic rats, Ian1 exhibits wild-type expression patterns, whereas Ian4 expression is reduced. Mutational screening of their coding sequences revealed a frameshift mutation in Ian4 among lymphopenic rats. The mutation results in a truncated protein in which the COOH-terminal 215 amino acids-including the anchor localizing the protein to the outer mitochondrial membrane-are replaced by 19 other amino acids. We propose that Ian4 is identical to Iddm1.

Opitz syndrome is genetically heterogeneous, with one locus on Xp22, and a second locus on 22q11.2

Opitz syndrome (OS, McKusick 145410) is a well described genetic syndrome affecting multiple organ systems whose cardinal manifestations include widely spaced eyes and hypospadias (Fig. 1). It was first reported as two separate entities, BBB syndrome, and G syndrome. However, subsequent reports of families in which the BBB and G syndrome segregated within a single kindred suggested that they were a single clinical entity. Although the original pedigrees were consistent with X-linked and autosomal dominant inheritance, male-to-male transmission in subsequent reports suggested that OS was inherited as an autosomal dominant trait. Here we report that OS is a heterogeneous disorder, with an X-linked and an autosomal locus. Three families were linked to DXS987 in Xp22, with a lod score of 3.53 at zero recombination. Five families were linked to D22S345 from chromosome 22q11.2, with a lod score of 3.53 at zero recombination. This represents the first classic multiple congenital anomaly syndrome with an X-linked and an autosomal form.

Blimp-1, a novel zinc finger-containing protein that can drive the maturation of B lymphocytes into immunoglobulin-secreting cells

We describe a novel gene, Blimp-1 (for B lymphocyte-induced maturation protein), transcripts of which are rapidly induced during the differentiation of B lymphocytes into immunoglobulin secretory cells and whose expression is characteristic of late B and plasma cell lines. The 856 amino acid open reading frame contains five Krüppel-type zinc finger motifs and proline-rich and acidic regions similar to those of known transcription factors. Serological studies show an approximately 100 kd protein that localizes to the nucleus. Stable or transient transfection of Blimp-1 into B cell lymphoma lines leads to the expression of many of the phenotypic changes associated with B cell differentiation into an early plasma cell stage, including induction of J chain message and immunoglobulin secretion, up-regulation of Syndecan-1, and increased cell size and granularity. Thus, Blimp-1 appears to be a pleiotropic regulatory factor capable of at least partially driving the terminal differentiation of B cells.

A novel X-linked member of the human zinc finger protein gene family: isolation, mapping, and expression

We report the partial characterization of a novel putative zinc finger gene of the Krüppel-type (ZNF81), isolated from an X Chromosome (Chr) specific library. The pattern of segregation in human-hamster somatic cell hybrids of sequences homologous to the ZNF81 finger domain has established that it resides within the Xp22.1-Xp11 region. ZNF81 represents yet another example, together with ZFX, ZNF41, and ZNF21, of members of the zinc finger gene family residing within the short arm of the human X Chr. Sequence analysis showed that ZNF81 may encode a polypeptide(s) containing tandem arrays of 12 canonical C2H2 zinc fingers of the Krüppel-type at the C-terminus. Northern analysis indicated that probes from the ZNF81 finger domain hybridize to polyadenylated transcripts present in several cell lines, a result that supports the hypothesis that it is an expressed, functional member of this multigene family.

Isolation of a zinc finger motif (ZNF75) mapping on chromosome Xq26

We report here the partial characterization of a new human zinc finger (ZNF75) gene of the Kruppel type mapping to the long arm of the X chromosome. A cosmid clone was isolated from a library specific to the Xq24-qter region by hybridization to a degenerate oligonucleotide representing the link between two contigous fingers of the C2H2 type. The sequence of the pertinent cosmid fragments demonstrated five consecutive zinc finger motifs, all pertaining to the Kruppel family. A reading frame starting at least 75 amino acids before the first zinc finger and ending 11 amino acids after the last one was identified; comparison with other ZF genes suggests that this genomic fragment represents the carboxy-terminal exon of the gene. Homology of approximately 55% in the zinc finger region was detected with many zinc finger genes including mouse Zfp-35 and human ZFN7 cDNA clones. Mapping using a panel of sematic cell hybrids and chromosomal in situ hybridization localized the gene to Xq26, in a region not previously known to contain zinc finger genes.

Convergent transcription initiates from oppositely oriented promoters within the 5' end regions of Drosophila melanogaster F elements

Drosophila melanogaster F elements are mobile, oligo(A)-terminated DNA sequences that likely propagate by the retrotranscription of RNA intermediates. Plasmids bearing DNA segments from the left-hand region of a full-length F element fused to the CAT gene were used as templates for transient expression assays in Drosophila Schneider II cultured cells. Protein and RNA analyses led to the identification of two promoters, Fin and Fout, that transcribe in opposite orientations. The Fin promoter drives the synthesis of transcripts that initiate around residue +6 and are directed toward the element. Fin, that probably controls the formation of F transposition RNA intermediates and gene products, is internal to the transcribed region. Sequences important for accumulation of Fin transcripts are included within the +1 to +30 interval; an additional regulatory element may coincide with a heptamer located downstream of this region also found in the 5' end regions of F-like Drosophila retrotransposons. Analysis of the template activity of 3' deletion derivatives indicates that the level of accumulation of Fin RNA is also dependent upon the presence of sequences located within the +175 to +218 interval. The Fout promoter drives transcription in the opposite orientation with respect to Fin. Fout transcripts initiate at nearby sites within the +92 to +102 interval. Sequences downstream of these multiple RNA start sites are not required for the activity of the Fout promoter. Deletions knocking out the Fin promoter do not impair Fout transcription; conversely, initiation at the Fin promoter still takes place in templates that lack the Fout promoter. At a low level, both promoters are active in cultured cells.

Members of the zinc finger protein gene family sharing a conserved N-terminal module

We report the isolation of human members of a sub-family of structurally related finger protein genes. These potentially encode polypeptides containing finger motifs of the Krüppel type at the C-terminus, and a conserved amino acid module at the N-terminus; because of its invariant location the latter is referred to as finger preceding box (FPB). The FPB, detected also in previously described finger proteins from human, mouse and Xenopus, extends over approximately 65 amino acids and appears to be composed of two contiguous modules: FPB-A (residues 1-42) and FPB-B (residues 43-65). The latter is absent in some of the members analyzed. Elements A and B and the zinc finger domain are encoded by separate exons in the ZNF2 gene, a human member of this sub-family. The positioning of introns within this gene is remarkable. One intron flanks and a second interrupts the first codon of the FPB-A and FPB-B modules, respectively. A third intron occurs a few nucleotides downstream of FPB-B marking its separation from the remainder of the coding sequences. This organization, together with the absence of FPB-B in some cDNAs, supports the hypothesis that mRNAs encoding polypeptides that include one, both or none of the FPB-A and FPB-B modules may be assembled through alternative splicing pathways. Northern analyses showed that members of this sub-family are expressed as multiple transcripts in several cell lines. The sequences of distinct cDNAs homologous to the ZNF2 gene indicate that alternative splicing events adjoin either coding or non coding exons to the FPB sequences.

Convergent transcription initiates from oppositely oriented promoters within the 5' end regions of Drosophila melanogaster F elements

Drosophila melanogaster F elements are mobile, oligo(A)-terminated DNA sequences that likely propagate by the retrotranscription of RNA intermediates. Plasmids bearing DNA segments from the left-hand region of a full-length F element fused to the CAT gene were used as templates for transient expression assays in Drosophila Schneider II cultured cells. Protein and RNA analyses led to the identification of two promoters, Fin and Fout, that transcribe in opposite orientations. The Fin promoter drives the synthesis of transcripts that initiate around residue +6 and are directed toward the element. Fin, that probably controls the formation of F transposition RNA intermediates and gene products, is internal to the transcribed region. Sequences important for accumulation of Fin transcripts are included within the +1 to +30 interval; an additional regulatory element may coincide with a heptamer located downstream of this region also found in the 5' end regions of F-like Drosophila retrotransposons. Analysis of the template activity of 3' deletion derivatives indicates that the level of accumulation of Fin RNA is also dependent upon the presence of sequences located within the +175 to +218 interval. The Fout promoter drives transcription in the opposite orientation with respect to Fin. Fout transcripts initiate at nearby sites within the +92 to +102 interval. Sequences downstream of these multiple RNA start sites are not required for the activity of the Fout promoter. Deletions knocking out the Fin promoter do not impair Fout transcription; conversely, initiation at the Fin promoter still takes place in templates that lack the Fout promoter. At a low level, both promoters are active in cultured cells.